JP2022513267A - Production of maleic acid by oxidation method - Google Patents

Abstract

The present invention relates to a method for producing maleic acid or a derivative thereof. The method comprises electrochemical oxidation of the floic acid compound to maleic acid in an electrolyte solution and may optionally further include the step of reacting maleic acid with its derivative. In an alternative embodiment, the method comprises a first step comprising electrochemical oxidation of the furan compound to one or more intermediates in an electrolyte solution, followed by maleic acid or a derivative thereof. Includes a second step involving the chemical catalytic oxidation of the above intermediate for.

Description

The present invention is in the field of chemical production of maleic acid and its derivatives. In particular, the present invention is directed to the sustainable chemical production of maleic acid and its derivatives using biomass-derived starting materials.

Current industrial methods for producing maleic acid are typically based on the oxidation of petrochemicals such as butane or benzene. It is desired to replace petrochemicals with biomass-based chemicals in order to reduce the environmental impact of production and provide a more sustainable route to maleic acid. See, for example, Wojcieszak et al., Sustainable Chemical Processes, 2015, 3: 9, 1-11. For example, the Journal of Organic Chemistry, 1986, 51 (4), 567-569 discloses the chemical oxidation of furfural, a chemical derivatized from biomass, with hydrogen peroxide. The drawback of such a chemical oxidation reaction is the need for hydrogen peroxide as an oxidant, because hydrogen peroxide must be produced in a separate manufacturing process. Therefore, the overall advantage of using chemicals that can be derived from biomass is diminished. Alternatively, Furfural is disclosed in UK Patent GB253877, Mil'man et al., Elektrokhimiya, 1978, Volume: 14, Issue: 10, 1555-1558, and Hellstroem: Svensk Kemisk Tidskrift, 1948, Volume 60, 214-220. It can be electrochemically oxidized as it is. However, the drawbacks of both of these known methods for producing maleic acid are that furfural is used as a starting material, and its one-pot oxidation process is time consuming and usually achieves acceptable kinetics. To require the presence of a mediator. However, mediators are generally unfavorable for large-scale methods because of the additional cost and often difficult to recycle.

In addition, furfural is relatively unstable, which means that furfural usually contains significant amounts of impurities, which causes a rapid change in color after distillation (eg to orange / brown). ). This instability is particularly problematic in continuous methods where the concentration of impurities increases with recycling. Therefore, further purification (and therefore additional cost) is required in the recycling loop where contaminants enter. In addition, these impurities can also cause problems with the desired reaction. Also, impurities can vary from batch to batch, which can lead to unpredictable results.

British Patent No. 253877

Wojcieszak et al., Sustainable Chemical Processes, 2015, 3: 9, 1-11 Journal of Organic Chemistry, 1986, 51 (4), 567-569 Mil'man et al., Elektrokhimiya, 1978, Volume: 14, Issue: 10, 1555-1558 Hellstroem: Svensk Kemisk Tidskrift, 1948, Volume 60, 214-220

Therefore, it is preferred to provide a method for producing maleic acid that is free of these drawbacks, or at least one of those drawbacks.

We can achieve this by essentially two different types of processes, each process using a furan compound containing a 2-carbonyl substituent (hereinafter also referred to as a furan compound). I found. This furan compound can be represented by the formula I, in which R ¹ is H, CH ₂ OH, CO ₂ H, or CHO, and R ² is H, OH, C ₁ to C ₆ Alkyl or O (C ₁ to C ₆ alkyl). Esters, amides, acid halides, anhydrides, carboxyimidazoles, nitriles, and salts of compounds according to formula I are meant to be included herein by the term furan compound.

In the first aspect of the invention, the process for producing maleic acid or a derivative thereof comprises a one-step electrochemical oxidation of the furan compound to maleic acid, which electrochemical oxidation is a mediator. It is carried out in an electrolyte solution containing (mediator). This process is set forth in Scheme 1, where the furan compound is of formula I (where R ¹ is H, CO ₂ H, CH ₂ OH, or CHO and R ² is H, OH, C ₁ to C ₆ alkyl, or O (C ₁ to C ₆ alkyl) compounds), or esters, amides, acid halides, anhydrides, carboxyimmidates, nitriles, and salts thereof.

This process may further optionally include the step of reacting maleic acid with its derivative.

We have found that this process particularly benefits from the presence of mediators, especially in large scale applications. Suitable mediators are described below. In the absence of mediators, the reaction rate is too low to be properly applied to large scales. Without wishing to be bound by theory, we can find the reason for this low reaction rate in the formation of one or more intermediates, the electrochemical oxidation of which proceeds particularly slowly. I think that. These intermediates include cis-β-formylacrylic acid (also referred to herein as formyl-acrylic acid), which, under certain conditions, tautomers with 5-hydroxy-2 (5H) -furanone. It is believed that they can be in sexual equilibrium.

It is hypothesized that the ring-closed form (ie, 5-hydroxy-2 (5H) -furanone) cannot be electrochemically oxidized or can only oxidize very slowly, thus preventing this oxidation. At the preferred pH of the reaction, the equilibrium is almost completely on the furanone side, so a slow reaction occurs. In order to achieve an acceptable reaction rate, it is preferable to have a mediator.

However, the presence of mediators is not desirable, especially on a large scale. Typical mediators are expensive and large scale processes require recycling or immobilization of mediators to make the process economically feasible. For this reason, mediator immobilization is preferred, especially for processes involving one-step electrochemical oxidation. Most preferably, the mediator is immobilized in the immediate vicinity of or on the working electrode (see below for more details on the electrode). Nevertheless, the drawback of immobilization is probably the leaching of mediators, and the fact that immobilization limits the amount of mediators available (because of the limited surface area of the support), which also limits. It also limits speed on large scales.

Examples of suitable mediators immobilized on the electrode include doping the working electrode with the mediator (see below). We have surprisingly found that vanadium-doped electrodes are particularly suitable for carrying out this process. Therefore, vanadium-doped electrodes are another aspect of the invention. In this embodiment, the pH of the electrolyte solution is preferably in the range of 3-7, even 5-6, in order to limit vanadium leaching. However, the drawback of this approach is that the process of preparing maleic acid is carried out at a lower pH (ie typically less than 5) so that free acid (CO _2H ) is obtained instead of salt. Is preferable. In addition, the use and immobilization of mediators is still costly, cumbersome and therefore disadvantageous.

Considering the remaining drawbacks and challenges of one-step electrochemical oxidation by the present invention, another aspect of the invention comprising a two-step (two-step) approach is preferred. This particular aspect of the invention comprises a first step comprising electrochemically oxidizing the furan compound to one or more intermediates in an electrolyte solution, followed by the intermediates being maleic anhydride or its intermediates. It relates to a process comprising a second step comprising chemically catalytic oxidation to a derivative, eg maleic anhydride. In the context of the present invention, chemically catalyzed oxidation can be considered as non-electrochemical oxidation. Other examples of non-electrochemical oxidation that can be adequately used in the present invention include photochemical oxidation and photoelectrochemical oxidation.

The process using the two-step approach (also referred to here as the two-step process) is shown in Scheme 2.

Again, this process may further include, optionally, reacting maleic acid with its derivative. As mentioned above, the one or more intermediates typically include 5-hydroxy-2 (5H) -furanone and / or cis-β-formylacrylic acid.

The advantage of the two-step process is that it does not require a mediator. Therefore, the electrolyte solution is preferably essentially media-free.

The inventors have surprisingly found that the chemically catalyzed oxidation of formyl-acrylic acid proceeds relatively easily, in contrast to the electrochemical oxidation. Typical conventional conditions for oxidizing aldehydes to carboxylic acids can be used. Suitable oxidizing agents in this regard can be chlorates, permanganates, hydrogen peroxide and the like. However, these methods can involve the formation of unwanted salts in the process. However, we have surprisingly found that 5-hydroxy-2 (5H) -furanone and / or cis-β-formylacrylic acid is maleic acid or its own by molecular oxygen (O ₂ ), also known as oxygen. It was discovered that it could be oxidized to a derivative. Therefore, chemical catalytic oxidation can be carried out by using oxygen as the oxidant in the presence of the catalyst. Suitable oxidation catalysts in this regard include transition metals such as palladium, copper, and / or platinum supported on activated carbon, as described in more detail below.

Thus, in certain embodiments of the invention, the method comprises 5-hydroxy-2 (5H) -furanone and / or cis-β-formylacrylic acid in the presence of a catalyst, molecular oxygen (O ₂ ). Including the step of oxidizing 5-hydroxy-2 (5H) -furanone and / or cis-β-formylacrylic acid to maleic acid or a derivative thereof by contact with, the step is referred to as O ₂ in the present specification. This is called the second step to be used.

We have discovered that some metals, especially transition metals, can adequately catalyze the oxidation reaction in the second step with O ₂ . Particularly good results were obtained with copper, gold, palladium, platinum, and ruthenium, especially gold.

The catalyst preferably further comprises a solid support (solid carrier). The solid support can be a support (carrier) known in the art, and in general, any support may be suitable as long as it is not harmful to the oxidation reaction. Typically, the solid support is inactive in the second step using O ₂ . Examples of supports that have been found to be suitable for the present invention include activated carbon, aluminum oxide, zinc oxide, and titanium dioxide. Titanium dioxide as a solid support, especially titanium dioxide in combination with gold, gave particularly good results with respect to the yield of maleic acid.

The second step using O ₂ of the present invention is generally carried out in the liquid phase rather than the gas phase. Due to the instability of the furan compound and HFO at high temperatures required to keep the compound gaseous, the gas phase reaction conditions are not well suited to the present invention. Therefore, it is preferred that the HFO and / or formylacrylic acid is liquid or dissolved in a solvent when contacted with O ₂ . Suitable solvents include both organic and aqueous solvents. Water immiscible organic solvents and acidic aqueous solvents are particularly preferred for the reasons detailed below. Water, aqueous sulfuric acid, acetic acid, ethyl acetate, methyl isobutyl ketone (MIBK), methyl tert-butyl ether (MTBE), 2-methyltetrahydrofuran (2-MeTHF), dichloromethane, heptane, acetonitrile, acetone, nitromethane, and toluene, preferably Good conversion of HFO and / or formylacrylic acid was obtained in 2-MeTHF, toluene, and MTBE.

Solvents capable of performing the second step with O ₂ can affect the products formed. For example, in an organic solvent, maleic anhydride can be formed by an in-situ dehydration reaction of maleic acid or when the HFO is directly oxidized by a catalyst. On the other hand, in an aqueous solvent, maleic acid itself is usually formed under acidic conditions, and maleic acid salts can be formed under basic conditions. Under certain reaction conditions, maleic acid can also be isomerized to fumaric acid, at least in part. The reaction conditions under which the second step with O ₂ is carried out also usually affect the products formed.

Oxidation processes have been found to give the best results for conversion under moderate reaction conditions including slightly higher temperatures and pressures. Therefore, the second step using O ₂ is preferably carried out under a pressure of at least 5 bar, preferably at least 10 bar. The preferred temperature range for carrying out the second step using O ₂ is 20 to 200 ° C, more preferably 50 to 150 ° C, and most preferably 60 to 100 ° C. These conditions allow continuous reactions to be carried out, for example in a tube reactor, which is preferred. Thus, the reactor can include a fixed catalyst bed containing a catalyst.

The starting material, HFO and / or formylacrylic acid, is an isolated (ie, essentially pure) formulation or reaction mixture obtained from the previous process in the _second step with O2. Can be supplied or provided. Isolated formulations can be obtained by prior processes and isolation that are not part of the invention. This preceding reaction can be any type of reaction process, for example can be useful in producing HFO and / or formylacrylic acid as the main product, or HFO and / or formylacrylic acid. It can be produced in the process as a by-product. In a preferred embodiment of the invention, the HFO and / or formylacrylic acid is derived from one or more furan compounds of biomass origin.

It has been found that it is particularly beneficial to carry out a second step using O ₂ in accordance with the present invention in combination with the electrochemical oxidation of furan compounds, because at the preferred pH of electrochemical oxidation, with HFO. This is because the equilibrium with formylacrylic acid is almost entirely on the HFO side, which causes slow oxidation. Acceptable kinetics in electrochemical oxidation can be achieved by applying mediators, but the presence of mediators, however, is not preferred, especially on a large scale. Typical mediators are expensive, and large scale processes require recycling or immobilization of mediators to make the process economically feasible. The second step using O ₂ according to the present invention shows a good reaction of HFO and formylacrylic acid, and therefore, two steps (two steps) including the first step combined with the second step using O ₂ . Process is preferred as a whole.

It can be understood that during the first step of the two-step process, some amount of maleic acid can be formed before all the starting materials are consumed, because of the first step. The condition is relatively low speed, but still allows this conversion.

The chemical catalyst oxidation is preferably carried out at a slightly elevated temperature. Temperatures in the range of 20-150 ° C, preferably in the range of 30-130 ° C, more preferably in the range of 50-100 ° C are typically suitable. Under these conditions, a reaction time of several hours (eg, 1-4 hours) is usually sufficient to reach complete conversion.

If the first step is carried out in an aqueous electrolyte solution (preferably, see below), the second step is to use the same solution, but after a pH shift or in an organic solvent, the above intermediate. It can be carried out after extraction. For the latter embodiment, it is preferable to carry out the second step in the organic solvent. It is understood that this embodiment includes a process in which the organic extract is subjected to intermediate drying, and in which it is not dried prior to further use. Typical organic solvents are suitable as long as they do not react in chemically catalyzed oxidation, otherwise they are detrimental to this step. Examples of organic solvents that can be used include dichloromethane, toluene, ethyl acetate, 2-methyltetrahydrofuran and the like. In this particular embodiment, maleic anhydride can be obtained directly from the process without a separate subsequent dehydration step. It is also possible to directly obtain maleic acid mono and / or diesters by chemical catalytic oxidation in alcohol.

In embodiments of the invention in which the first and second steps are carried out in the same solution, this process isolates maleic acid or its derivatives, isolated maleic acid or its derivatives, and used. Further comprises the steps of resulting in an electrolyte solution of. The used electrolyte solution can be recycled for this process. The used electrolyte solution may contain residual furan compounds, intermediates of this process, maleic acid, and other impurities and / or polymers formed. Therefore, it may be preferable to purify the used electrolyte solution prior to recycling (eg, nanofiltration to remove polymeric material). As an alternative to purification or in addition to purification, it may be preferable to remove some of the recycled electrolyte and add new ones to maintain a constant quality of electrolyte.

Isolation of maleic acid or its derivatives can be carried out using standard isolation methods such as distillation. A particularly preferred method of isolation can depend on the solvent used. By isolating maleic acid, the pH of the electrolyte solution can be returned to the original pH, that is, the pH at the start of oxidation. Therefore, it may not be necessary to adjust the pH with additives. If any electrolyte, acid, solvent, or water is lost or consumed during the oxidation of the furan compound or isolation of maleic acid, replenish the acid, solvent, or water during recycling of the electrolyte solution. Can be done.

Recycling of the electrolyte solution is particularly preferred when the process is a continuous process and is carried out, for example, in a continuous reactor system. Therefore, the reactor system in which the process is carried out can include a recycling loop for the electrolyte solution. Recycling the electrolyte solution can advantageously result in minimal chemical waste generation and reduced external input.

Performing the second step above in an alkaline solvent at high pH (eg, above 7) yields very high yields of maleate.

Both aspects of the invention share many features and properties. For brevity and clarity, not all features are expressly attributed to individual aspects, but unless it occurs logically or explicitly. It can be understood that all the features described in can be used for both aspects.

Further, it can be understood that the second step can be performed separately from the first step. Therefore, chemical catalytic oxidation of intermediates, especially 5-hydroxy-2 (5H) -furanone and / or cis-β-formylacrylic acid, is also part of the invention.

As mentioned above, 2-furoic acid compounds (also referred to herein as furoic acid) are advantageously more stable than furfural and produce 2,5-furandicarboxylic acid (FDCA). It can be obtained as a by-product in, or by stabilizing furfural by direct oxidation to floric acid, which is generally under mild conditions (eg, reaction temperature below 100 ° C.). Is a clean, high yield process. Therefore, the use of 2-furoate compounds is preferred. In addition, the application of floric acid in the chemical process according to the invention is also advantageous, as it is believed that there is currently no envisioned significant market for floric acid.

The inventors have surprisingly found that the use of floic acid to produce maleic acid and the replacement of furfural with floric acid are particularly advantageous in electrochemical oxidation reactions. Electrochemical reactions tend to have significantly longer residence times than thermochemical reactions (see below due to the limitation of the surface area of the electrode and the transfer of material to / from the electrode surface). Chemicals often remain in the solution for a very long time, where they are susceptible to decomposition. Therefore, the electrochemical oxidation process for producing maleic acid is particularly beneficial due to the improved stability of the starting material. Thus, oxidation involves electrochemical oxidation in an electrolyte solution, typically an aqueous electrolyte solution containing said floric acid compound, or, in the first aspect, consists solely of that electrochemical oxidation. Therefore, the addition of an oxidizing agent, such as hydrogen peroxide, may not be necessary. Typically, the process comprises dissolving the furoic acid compound in an electrolyte solution and then electrochemically oxidizing it to convert the furoic acid or a derivative thereof to maleic acid.

A particular embodiment of the invention comprises chemically catalyzing furfural to floric acid prior to electrochemical oxidation of floric acid.

A floric acid compound is based on 2-fluoroacid and has the same oxidation state as floric acid, which means any compound that can be oxidized to maleic acid. Examples of suitable floric acid compounds include 2-fluoroacid, floric acid ester, floic acid amide, flonitrile, hydrofluoric acid anhydride, froic acid carboxylimide, floic acid halide, and salt of floric acid. Is done. In particular, due to its good solubility in water (about 37.1 g / L in water at 15 ° C., about 100 g / L in water at 50 ° C.), it is preferred to use 2-fluoroacid as the floric acid compound.

It has been discovered that maleic acid can be obtained directly by the oxidation process according to the invention, especially when the process is carried out in an aqueous environment. This is in contrast to conventional oxidation processes based on benzene and butane, where maleic anhydride is first obtained and can only be converted to maleic acid in subsequent hydrolysis steps. However, like maleic acid, maleic anhydride is also an industrially available chemical and therefore it may be preferable for the process to include the preparation of maleic acid derivatives such as maleic anhydride. Therefore, the process may optionally include the step of further reacting maleic acid with a derivative thereof, such as maleic anhydride. If the process is carried out at least partially in an organic solvent, preferably under anhydrous conditions, maleic anhydride can be obtained directly from the process without a separate subsequent dehydration step.

The direct formation of maleic anhydride by chemical catalytic oxidation is as shown in Scheme 3, which is a particularly preferred embodiment of the present invention.

Derivatives of maleic acid that can be obtained in the step of further reacting maleic acid can include fumaric acid, succinic acid, and salts, esters, anhydrides, amides, or imides thereof. This optional additional reaction step to result in maleic anhydride, fumaric acid, succinic acid, or salts, esters, or anhydrides thereof as such (ie, without prior oxidation of the furan compound) is the art of the art. Is known at. For example, maleic anhydride, fumaric acid, and succinic acid can be obtained from maleic acid by dehydration reaction, isomerization reaction, and partial hydrogenation reaction, respectively. Fumaric acid is currently produced (mainly) on an industrial scale by catalytic isomerization of maleic acid. Succinic acid is also industrially produced by partial reduction of maleic acid, which is one of several known pathways.

As mentioned above, we are even more surprising that the electrochemical oxidation of the furan compound to maleic acid is in tautomeric equilibrium with 5-hydroxy-2 (5H) -furanone under certain conditions. It has been discovered that it can proceed via cis-β-formylacrylic acid (also referred to herein as formylacrylic acid) as an intermediate capable. Therefore, another aspect of the invention is the preparation of cis-β-formylacrylic acid and / or 5-hydroxy-2 (5H) -furanone from furan compounds. Sis-β-formylacrylic acid and / or 5-hydroxy-2 (5H) -furanone prepared by electrochemical oxidation according to the present invention can be isolated or further reacted with maleic acid or its derivatives. Can be made to. This further reaction can also be carried out electrochemically, particularly according to the processes and parameters described herein. Alternatively, as described above, cis-β-formylacrylic acid and / or 5-hydroxy-2 (5H) -furanone is a chemically catalyzed oxidation, biotechnology-based process, such as oxygen-based thermochemical oxidation type conditions. Alternatively, it can be further oxidized to maleic acid and / or maleic anhydride by photooxidation. This is the case when the electrochemical oxidation of the furan compound to maleic acid is rate-determining in the conversion of cis-β-formylacrylic acid and / or 5-hydroxy-2 (5H) -furanone to maleic acid, and the mediator. Especially preferred for large scale processes where the use of is not preferred.

In the electrochemical oxidation according to the present invention, lead oxide, for example, lead oxide may be optionally a metal such as Pb, porous graphite such as activated carbon, carbon nanotube (CNT), reticulated glassy carbon (RVC), or It is carried out using one or more working electrodes (here also referred to as an anode electrode, an anode, or simply an electrode) containing PbO ₂ which may be carried on carbon felt or boron-doped diamond (BDD). Is preferable. The activity of the electrode can be improved by adding a dopant or adsorbed atom (to the electrode or electrolyte). For example, the addition of metal ions such as Fe ²⁺ or Fe ³⁺ to the electrolyte can improve the stability of PbO ₂ . In principle, any electrode structure can be used, including 2D and 3D structures, but one or more porous electrodes, fusion electrodes, mesh electrodes, nanostructured electrodes, porous carbon / graphite electrodes. One or more electrodes containing the metal or metal oxide particles carried on top, or a combination thereof, are preferred. Such electrodes result in higher conversion rates. In certain embodiments, the working electrode is an alternative or additional, mixed metal oxide (MMO), dimensionally stable anode (DSA), stainless steel, brass carbon based graphite electrode, Pt, Au. , Ag, Cu, Ir, Ru, Pd, Ni, Co, Zn, Cd, In, Sn, Ti, Fe, and one or more of their alloys or oxides.

The counter electrode (also referred to as a cathode electrode or cathode) is one or more selected from the group consisting of Au, Pt, Pd, Ir, Ru, Ni, Co, stainless steel, Cu, carbon, Pb, Ti, or alloys thereof. Can contain substances of. Advantageously, the process of the present invention also allows electrochemical reductions, such as the production of hydrogen from water, the reduction of oxygen to water, or the conversion of furfural to furfuryl alcohol simultaneously at the cathode. , May include paired electrochemical synthesis.

In certain embodiments, the working electrode is doped with a mediator (see below). We have surprisingly found that vanadium-doped electrodes are particularly suitable for carrying out this process. Therefore, vanadium-doped electrodes are another aspect of the invention. In this embodiment, the pH of the electrolyte solution is in the range of 3-7, more preferably 4-5, in order to limit vanadium leaching.

Oxidation of the furan compound can be done directly on the electrode. This means that electrons from the oxidant or electrode move directly to the furan compound or chemical intermediate in the reaction. Alternatively, it can be carried out by using a mediator that receives and temporarily retains an electron from the electrode and then transfers the electron to a furan compound (or a chemical intermediate in the reaction). The presence of the mediator may not eliminate the oxidation at the electrode, but in the presence of this, the oxidation usually proceeds primarily through the mediator. Preferably, the mediator is ^vanazine salt, vanadium oxide (eg ^V2O ₅ , VO ₂ ), molybdate ₍ MoO _4-2 ), chromate (CrO _4-2 ), dichromate (Cr). ₂ O ₇ ^2- ), permanganate (MnO _4- ⁾ , manganese (MnO _4-2 ), manganese salt (Mn ²⁺ ), ^tungstate (WO ^4-2 ) _{, iodate (IO 3 )} ^- ) Chlorate ( ^ClO- ), Chlorate-Chlorate couple (Cl ⁻ / Cl ₂ ), Bromine salt (BrO ⁻ ), Bromide-Bromide couple (Br ⁻ / Br ₂ ), Peroxodisulfate (S ₂ ) Contains one or more of O ₈ ^2- ), ozone (O ₃ ), cobalt salt (Co ²⁺ / Co ³⁺ ), cerium salt (Ce ³⁺ / Ce ⁴⁺ ) and the like. Most preferably, the mediator comprises vanadium oxide, sodium molybdate, and / or potassium dichromate.

Surprisingly, we have found that the oxidation reaction proceeds satisfactorily in the absence of mediators. This process is due to cost, safety issues (mediators are often very toxic / carcinogenic), increasing process complexity (mediator recapturing / recycling), and environmental impact of the process. May be preferred to be performed without a mediator. Therefore, the electrolyte solution is essentially free of mediators, preferably during electrochemical oxidation. In the context of the present invention, essentially free is preferably less than 5 mol%, preferably less than 1 mol%, based on the amount of furan compound starting material present at the initiation of the electrochemical oxidation reaction. It preferably means less than 0.01 mol%. Most preferably, the electrolyte solution contains less than or equal to the trace amount of mediator. "At the beginning of the electrochemical oxidation reaction" means the moment just before the first amount of furan compound is oxidized.

Oxidation, especially electrochemical oxidation, proceeds particularly well in a particular pH range. Specifically the preferred pH range depends, among others, on the electrode or oxidant used, but the _pKa value of the furan compound can also partially determine the preferred pH range. Especially when the furan compound contains 2-furoate, is the electrochemical oxidation preferably at least partially equal to less than 7, more preferably less than 4, even more preferably less than 3, and most preferably approximately equal to 2. It is carried out at a pH less than 2.

Due to the conversion of the furan compound to maleic acid, the pH of the electrolyte solution may be lower than the pH value at the start of the reaction. Therefore, electrochemical oxidation is initiated at a pH value higher than the optimum value at which oxidation can be carried out, and during the conversion of the furan compound, the pH value drops to the optimum pH value or drops to the preferable pH value defined above. It is possible. Therefore, preferred pH values are defined for at least a portion of the duration of electrochemical oxidation (see above: "at least partially at pH ...") and not necessarily for electrochemical oxidation. There is no provision for the entire duration.

The pH can be adjusted by an external source during the process to maintain the optimum pH during all reactions (eg, addition of the appropriate acid or base). In addition, it can also be performed in the presence of a buffer to maintain pH. In addition, the desired pH range can be set by using a suitable solvent or a suitable electrolyte solution. Therefore, the solvent or electrolyte solution, if present, preferably contains an acid such as an organic acid and / or an inorganic acid. Inorganic acids are preferred, because, compared to organic acids, inorganic acids are more inert in the electrochemical oxidation reaction and are therefore preferred. More preferably, the inorganic acids are hydrochloric acid (HCl), nitric acid (HNO ₃ ), phosphoric acid (H ₃ PO ₄ ), sulfuric acid (H ₂ SO ₄ ), boric acid (H ₃ BO ₃ ), hydrofluoric acid (H 3 BO 3). It is selected from the group consisting of HF), hydrobromic acid (HBr), perchloric acid (HClO ₄ ), and hydroiodic acid (HI). Most preferably, the electrolyte solution contains sulfuric acid. In certain embodiments, the acid can be at least partially immobilized by incorporation into a resin (such as Amberlyst ™ or Nafion ™) that can be added to the mixture, and / or the acid. It can be structurally incorporated into one or more electrodes. In certain embodiments, the electrolyte may preferably contain an acid in combination with an inorganic salt in order to increase the ionic conductivity of the electrolyte. For example, if the pH of the electrolyte is desired to be 1, the acid concentration may not be sufficient to provide good conductivity and it may be preferable to add salts for that purpose. be.

The electrolyte solution can be aqueous or non-aqueous. Suitable non-aqueous electrolyte solutions are acetone, sulfolane, dimethyl sulfoxide (DMSO), tetrahydrofuran (THF), dimethylformamide (DMF), N-methylpyrrolidone (NMP), hexamethylphosphoric acid triamide (HMPA), acetonitrile (MeCN). , Dichloromethane (DCM), propylene carbonate, hexafluoroisopropanol (HFIP), and ionic liquids (eg [C4mim] ⁺ and anion HSO _4- ^, CF ₃ CO _2- , H ₂ PO _4- ^{, Cl- ,} NO ₃ ^- , BF _4- ^, OTf- ^, PF _6- ⁾ contains one or more solvents selected from the group. In particular, in embodiments where the solvent is not an ionic liquid, the non-aqueous electrolyte solution preferably contains an inorganic salt or an organic salt as the electrolyte.

In order to increase the conversion rate of the furan compound to the intermediate or maleic acid, it may be preferable to carry out the electrochemical oxidation at a temperature in the range of 10 to 100 ° C, more preferably in the range of 15 to 70 ° C. Particularly for electrochemical oxidation, it is not common to perform oxidation at a temperature raised (that is, a temperature higher than room temperature). However, for this process, it has been found that elevated temperatures, especially temperatures of about 35-60 ° C., result in increased conversions and yields as well as better solubility (ie, concentrations can increase somewhat). There is.

High concentrations of starting material in the reaction solvent are usually advantageous for achieving high conversion rates in chemical redox reactions, but this may not be the case for electrochemical oxidation reactions, because This is because the rate-determining step is usually mainly determined by the electron density in the electrode and not so much by the concentration of the reaction raw material in the solution. In other words, the surface area and current of the accessible electrodes mainly affect the conversion rate. High concentrations of starting material in the reaction solvent are usually advantageous for achieving high conversion rates in chemical redox reactions, but this may not be the case for electrochemical oxidation reactions. In general, in such a process, increasing the concentration increases the current to a value of dynamic current determined by the nature of the electrode, the surface area of the electrode, the molecules that react, the adsorption properties on the electrode, and so on. Then, the reaction will not proceed fast. The reaction will be limited by the exchange of the formed product at the electrode with new reaction material. In other words, the surface area, current, and mass transfer of the accessible electrodes usually have a large effect on the conversion rate. Therefore, higher concentrations may not necessarily result in an increased reaction rate, but may only result in a longer reaction time, which in turn may only result in decomposition of the reaction feedstock, intermediates, or products. This is not particularly desirable for continuous flow reactions, which may not reach such complete conversion. Thus, in embodiments where the process comprises electrochemical oxidation, electrochemical oxidation involves a concentration of furan compounds in the electrolyte solution in the range of 0.01-5 mol / L, preferably 0.1 mol / L-3. It is preferably carried out in the range of 5.5 mol / L, more preferably 0.3 mol / L to 2 mol / L. This range resulted in particularly good conversion rates and yields. As the concentration can decrease over time, as used herein, the concentration means the initial concentration of the furan compound, i.e. the concentration at the start of the reaction.

In a preferred embodiment, the electrochemical oxidation is carried out in a two-layer electrochemical cell, in which the anodic electrolyte solution and the cathode electrolyte solution are cations (eg, depending on the specific characteristics of the process). It is separated by a semipermeable membrane (such as an exchange membrane (CEM) or anion exchange membrane (AEM)). This embodiment is particularly suitable for carrying out the process on a large scale, because it prevents or at least limits the reduction of the reaction product at the cathode, and it is a furan compound. Will reduce efficiency in both cases, whether the reaction product is reduced at the cathode or the furan compound travels over the cathode. Let's do it. Suitable membranes for this embodiment include Nafion ™, Fumatech ™, Neospta ™, and / or Selemion ™ in trade names. Porous diaphragm / glass frit may also be sufficient.

In a preferred embodiment of the invention, the process further comprises the step of isolating maleic acid or a derivative thereof to yield the isolated maleic acid or a derivative thereof, and a used electrolyte solution. The used electrolyte can be recycled in this process. The used electrolyte solution may contain residual furan compounds, intermediates of this process, maleic acid, and other impurities and / or polymers formed. Therefore, it may be preferable to purify the used electrolyte solution prior to recycling (eg, nanofiltration to remove polymeric material). Instead of or in addition to purification, it may be preferable to remove some of the recycled electrolyte and add new material to maintain a constant quality of electrolyte.

Isolation of maleic acid or its derivatives can be performed using standard isolation techniques such as distillation. A particularly preferred isolation method may depend on the solvent used. By isolating maleic acid, the pH of the electrolyte solution can be returned to the original pH, that is, the pH at the start of oxidation. Therefore, it may not be necessary to adjust the pH with additives. If some electrolyte, acid, solvent, or water is lost or consumed during the oxidation of the furan compound or the isolation of maleic acid, replenish the acid, solvent, or water during the recycling of the electrolyte solution. be able to.

Recycling of the electrolyte solution is particularly preferred when the process is a continuous process and is carried out, for example, in a continuous reactor system. The reactor system in which this process is carried out can therefore include a recycling loop of electrolyte solution. Recycling the electrolyte solution can advantageously result in minimal chemical waste generation and reduced external input.

Advantageously, the process may also allow simultaneous electrochemical reductions, such as the production of hydrogen from water, or the conversion of furfural to furfuryl alcohol, at the cathode. It may also be possible to reduce oxygen to water in order to reduce cell voltage and energy consumption.

It can be understood that electrochemical oxidation here is particularly preferred in order to minimize the formation of chemical waste. The formation of chemical waste is to carry out the process of the present invention with an electrolyte solution consisting essentially of water, furan compounds, acids (as electrolytes), and possible reaction intermediates, as well as products such as maleic acid. Can be further suppressed by. In other words, although possible, the presence of additives such as salts, stabilizers, buffers, surfactants, etc. is not preferred and the electrolyte solution is preferably free of such additives. An additional advantage of the absence of salt in the electrolyte solution is that maleic acid can be obtained directly as a free acid, not necessarily as its salt. In industrial applications with maleic acid, the free acid is usually used, so the need for intermediate conversion of salt to free acid and the corresponding salt waste by providing free maleic acid in place of the salt. Is prevented from being generated.

As used herein, the wording of the singular is intended to include the plural unless the context clearly indicates otherwise. The term "and / or and / or" includes any combination of one or more of the related enumerated matters. It will be appreciated that the terms "contains" and / or "contains" specify the presence of the stated features, but do not preclude the presence or addition of one or more other features.

Features are described herein as part of the same or separate embodiments for the purposes of clarification and brief explanation, but the scope of the invention includes all or some combinations of the described features. It is understood that embodiments may be included. The present invention can be described by the following non-limiting examples.

<Example 1: Conversion of 2-methylfurate to maleic acid>
The anode compartment of the H cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 10 mM methyl furoate (methylfuroate) and 20 mM vanadium pentoxide. A 100 mL 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 22 cm ² PbO ₂ electrode was activated by cyclic voltammetry (CV) between 0.8 and 2.4 V relative to the standard hydrogen electrode (SHE). A reference electrode and a working electrode were prepared and a potential of 1.75 V was applied across the cell to the reversible hydrogen electrode (RHE). Analysis after 6 hours yields about 42% for maleic acid, indicating the presence of both residual methylfloate and the reaction intermediate formyl-acrylic acid.

<Example 2: Conversion of 2-furoate to maleic acid-Vanadium pentoxide mediator>
The anode compartment of the H cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 20 mM 2-furoate and 20 mM vanadium pentoxide. A 100 ml 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with CV between 0.5 and 2.1 V for SHE. A reference electrode and a working electrode were prepared and a potential of 1.6 V was applied across the cell to the saturated calomel electrode SCE. Analysis after 7 hours shows that the reaction intermediate formyl-acrylic acid: maleic acid: 2-furoate is present in a ratio of about 15: 4: 1.

<Example 3: Conversion of 2-furoate to maleic acid-vanadium pentoxide mediator and increased concentration>
The anode compartment of the H-cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 50 mM 2-furoate and 20 mM vanadium pentoxide. A 100 ml 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with CV between 0.8 and 2.1 V for SHE. A reference electrode and a working electrode were prepared, and a constant current of 0.2 A was applied. Analysis after 15 hours shows that the reaction intermediate formyl-acrylic acid: maleic acid ratio is about 2: 3.

<Example 4: Conversion of 2-furoate to maleic acid-vanadium pentoxide mediator, increased concentration, and heating>
The anode compartment of the H-cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 50 mM 2-furoate and 20 mM vanadium pentoxide. A 100 ml 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with CV between 0.8 and 2.1 V for SHE. A reference electrode and a working electrode were prepared and the cell contents were heated to 35 ° C. Next, a constant current of 0.2 A was applied. Analysis after 12 hours shows that the reaction intermediate formyl-acrylic acid: maleic acid is present in a ratio of about 9:11.

<Example 5: Conversion of 2-furoate to maleic acid-without mediator>
The anode compartment of the H cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 20 mM 2-furoate. A 100 ml 0.5M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with CV between 0.5 and 2.1 V for SHE. A reference and working electrodes were prepared and a potential of 1.84 V was applied across the cell to the SCE. Analysis after 19 hours shows that the reaction intermediate formyl-acrylic acid: maleic acid: 2-furoate is present in a ratio of about 25:74: 1.

<Example 6: Conversion of furfural to maleic acid-Vanadium pentoxide mediator>
The anode compartment of the H cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 20 mM furfural and 20 mM vanadium pentoxide. A 100 ml 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with a CV between 0.5 and 2.1 V against SHE. A reference electrode and a working electrode were prepared and a potential of 1.6 V was applied across the cell to the SCE. Analysis after 19 hours shows that the reaction intermediate formyl-acrylic acid: maleic acid has a ratio of about 5: 1.

<Example 7: Conversion of furfural to maleic acid-Vanadium pentoxide mediator>
The anode compartment of the H cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 40 mM furfural and 20 mM vanadium pentoxide. A 100 ml 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with a CV between 0.5 and 2.1 V against SHE. A reference electrode and a working electrode were prepared and a potential of 1.9 V was applied across the cell to the SCE. Analysis after 12 hours shows that maleic acid is present in about 80% yield.

<Example 8: Conversion of furfural to 5-hydroxy-2 (5H) -furanone>
The anode compartment of the H cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 50 mM furfural. Conversion at 20 ° C. A 100 ml 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with a CV between 0.5 and 2.1 V against SHE. A reference and working electrodes were prepared and a potential of 1.85 V was applied across the cell to the SCE. Analysis after 7 hours shows a ratio of about 2: 1 of the reaction intermediate formyl-acrylic acid: maleic acid present and about 9: 1 after 20 hours. The maximum total yield of product (maleic acid and 5-hydroxy-2 (5H) -furanone) is about 80%.

<Example 9: Conversion of furfural to 5-hydroxy-2 (5H) -furanone>
The anode compartment of the H cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 50 mM furfural. Conversion at 35 ° C. A 100 ml 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with a CV between 0.5 and 2.1 V against SHE. A reference and working electrodes were prepared and a potential of 1.85 V was applied across the cell to the SCE. Analysis after 7 hours shows the presence of the reaction intermediate formyl-acrylic acid: maleic acid in a ratio of about 1: 2, and after 20 hours about 1:10. The maximum total yield of product (maleic acid and 5-hydroxy-2 (5H) -furanone) is about 70%.

<Example 10: Conversion of furfural to 5-hydroxy-2 (5H) -furanone>
The anode compartment of the H cell was filled with 100 mL of 0.5 M aqueous sulfuric acid containing 50 mM furfural. Conversion at 50 ° C. A 100 ml 0.5 M aqueous sulfuric acid solution was placed in the cathode compartment of the H cell. A 10 cm ² PbO ₂ electrode was activated with a CV between 0.5 and 2.1 V against SHE. A reference electrode and a working electrode were prepared and a potential of 1.85 V was applied across the cell to the SCE. Analysis after 7 hours shows that the reaction intermediate formyl-acrylic acid: maleic acid is present in a ratio of about 1:34.

<Example 11: Extraction of cis-β-formylacrylic acid / 5-hydroxy-2 (5H) -furanone and maleic acid from the electrolyte>
The same volume of electrolyte and organic solvent from Example 9 (ethyl acetate, dichloromethane, toluene, 2-methyltetrahydrofuran, diethyl ether) were mixed vigorously together and then phase separated. Both the aqueous and organic phases were then analyzed by HPLC to determine the relative amount of cis-β-formylacrylic acid / 5-hydroxy-2 (5H) -furanone and maleic acid in each phase.

The conditions for using ethyl acetate were scaled up, the organic phase was separated from the aqueous phase, dried over sodium sulphate and then concentrated under reduced pressure (in vacuum) to give a white solid product (400 mg). rice field. This was analyzed by NMR, and it was confirmed that the ratio of cis-β-formylacrylic acid / 5-hydroxy-2 (5H) -furanone: maleic acid was about 2.7: 1.

<Example 12: Oxidation of cis-β-formylacrylic acid / 5-hydroxy-2 (5H) -furanone to maleic acid / acid anhydride>
In two separate reactors, cis-β-formylacrylic acid / 5-hydroxy-2 (5H) -furanone: maleic acid mixture (50 mg) isolated in Example 11, 5% potassium on carbon (25). mg) and a solvent (either 350 μL-0.5 M aqueous sulfuric acid solution, monopotassium phosphate or dipotassium phosphate pH 7 aqueous buffer) were added. The reactor was then heated to 70 ° C. with stirring and oxygen was bubbled through the mixture. After 2 hours, the reaction was cooled to room temperature and analyzed by HPLC. In both cases, cis-β-formylacrylic acid / 5-hydroxy-2 (5H) -furanone was converted to maleic acid.

<Example 14: Solvent for oxidizing HFO to maleic acid>
The autoclave (10 ml) was charged with HFO, solvent (1 ml), and 10% Pd / C according to Table 1 below.
The reactor was sealed and then flushed with nitrogen. The reactor was then charged with pure oxygen to a pressure of 10 bar. The reactor was then heated to 85 ° C. and stirred for 15 hours. After cooling to ambient temperature, the pressure was released and the reactor was flushed with nitrogen. The product solution was then filtered to remove the catalyst and then analyzed by high performance liquid chromatography (HPLC) and the yields of maleic acid are summarized in Table 1.

<Example 15: Catalyst for oxidizing HFO to maleic acid in toluene>
According to Table 2, HFO (10.6 mg), toluene (1 ml), and a catalyst were placed in an autoclave (10 ml). The reactor was sealed and then flushed with nitrogen. The reactor was then charged with pure oxygen to a pressure of 10 bar. The reactor was then heated to 111 ° C. and stirred for 14 hours. After cooling to ambient temperature, the pressure was released and the reactor was flushed with nitrogen. The product solution was then filtered to remove the catalyst and then analyzed by HPLC and the results are summarized in Table 2.

Claims (21)

A method for producing maleic acid or a derivative thereof, wherein the method comprises electrochemical oxidation of the furan compound to one or more intermediates in an electrolyte solution, wherein the method comprises the electrochemical oxidation of the furan compound to one or more intermediates.
The furan compound is a compound of formula I (in formula I, R ¹ is H, CH ₂ OH, CO ₂ H, or CHO, and R ² is H, OH, C ₁ to C ₆ alkyl, Or O (C ₁ to C ₆ alkyl)), or esters thereof, ethers, amides, acid halides, acid anhydrides, carboxyimidases, nitriles, and salts, comprising the first step;

A production method comprising this first step followed by a second step comprising chemically catalyzed oxidation of the intermediate to yield maleic acid or a derivative thereof. The method of claim 1, wherein the one or more intermediates comprises 5-hydroxy-2 (5H) -furanone and / or cis-β-formylacrylic acid.

The method according to claim 1 or 2, wherein the electrolyte solution is essentially media-free. Chemical catalytic oxidation is carried out in the presence of the catalyst by using oxygen as the oxidant, the catalyst preferably comprising a transition metal, a metal salt, a metal oxide, or a phosphate, more preferably. The metal according to any one of claims 1 to 3, wherein the metal is selected from the group consisting of cobalt, manganese, vanadium, molybdenum, copper, silver, gold, palladium, platinum, and ruthenium, most preferably gold. the method of. The method according to any one of claims 1 to 4, further comprising extracting the intermediate with an organic solvent and preferably carrying out the second step in the organic solvent. The method according to any one of claims 1 to 5, wherein the second step directly results in maleic anhydride.

The method of any one of claims 1-6, wherein the first step comprises photoelectrochemical oxidation. A method for producing maleic acid or a derivative thereof, wherein the method comprises a one-step electrochemical oxidation of a furan compound to maleic acid, wherein the electrochemical oxidation is carried out in an electrolyte solution containing a mediator. The furan compound is of formula I

(In the formula, R ¹ is H, CH ₂ OH, CO ₂ H, or CHO, and R ² is H, OH, C ₁ to C ₆ alkyl, or O (C ₁ to C ₆ alkyl)).
Compounds, or esters thereof, ethers, amides, acid halides, acid anhydrides, carboxyimidazoles, nitriles, and salts thereof.
A method of manufacture that may further optionally include the step of reacting maleic acid with its derivative. The mediators are ^vanadinate , vanadium oxide (eg V2 O ₅ , VO ₂ ), molybdenate (MoO _4-2 ), chromate _{(CrO 4-2), dichromate (Cr 2 O )} ^. ₇ ^2- ), permanganate (MnO _4-2 ⁾ , manganate (MnO _4-2 ), manganese salt (Mn ²⁺ ), tungstate (WO ^4-2 ) _, iodate ₍ IO ^{3- )} , Chlorate ( ^ClO- ), Chloride-Chlorine couple (Cl ⁻ / Cl ₂ ), Bromine salt (BrO ⁻ ), Bromide-bromine couple (Br ⁻ / Br ₂ ), Peroxo dissulfate (S ₂ O) ₈ ^2- ), ozone (O ₃ ), cobalt salt (Co ²⁺ / Co ³⁺ ), cerium salt (Ce ³⁺ / Ce ⁴⁺ ), etc., most preferably mediators are vanadium oxide, molybdenum acid. The method of claim 8, comprising sodium and / or potassium dichromate. The method of claim 8 or 9, wherein the mediator is immobilized, preferably immobilized on the surface of an electrode. The method according to any one of claims 1 to 10, wherein the electrolyte solution is an aqueous electrolyte solution. The derivative of maleic acid is selected from the group consisting of maleic anhydride, fumaric acid, succinic acid, succinic acid nitrile, putresin, malic acid, and salts, acid anhydrides, amides, imides, or esters of any of these compounds. The method according to any one of claims 1 to 11, wherein the method is one or more. The electrolyte solution is an acid, preferably a mineral acid, more preferably hydrochloric acid (HCl), nitric acid (HNO ₃ ), phosphoric acid (H ₃ PO ₄ ), sulfuric acid (H ₂ SO ₄ ), boric acid (H ₃ BO ₃ ). , A mineral acid selected from the group consisting of hydrofluoric acid (HF), hydrobromic acid (HBr), perchloric acid (HClO ₄ ), hydroiodic acid (HI), most preferably sulfuric acid. Item 1. The method according to any one of Items 1 to 12. The method according to any one of claims 1 to 13, wherein the electrochemical oxidation is carried out at a pH of less than 4, preferably less than 3, most preferably about 2 or less. The electrochemical oxidation is in the range of 0.01 to 5 mol / L, preferably 0.1 mol / L to 3.5 mol / L, more preferably 0.3 mol / L to 2 mol / L. The method according to any one of claims 1 to 14, which is carried out at the initial concentration of the furan compound in the electrolyte solution. 13. the method of. ₁₃ . The method described. It further comprises the step of isolating maleic acid or a derivative thereof to yield the isolated maleic acid or a derivative thereof, and a used electrolyte solution, preferably used after purification of the intermediate, optionally by option. The method of any one of claims 1-17, further comprising recycling the electrolyte solution. Any one of claims 1-18, which is a continuous method carried out in a continuous reactor system, preferably in a continuous reactor system in which the isolation of maleic acid is carried out continuously and / or in parallel in situ. The method described in the section. 13. Method. A method comprising a step of chemically catalytic oxidation of 5-hydroxy-2 (5H) -furanone and / or cis-β-formylacrylic acid to maleic acid or a derivative thereof, wherein chemical catalytic oxidation is preferred. A method performed by chemical catalytic oxidation specified in any one of 1 to 20.